摘要
研究人员使用超快光学光谱在研究La4Ni3O10单晶时,于密度波转变温度约136 K处观察到准粒子弛豫动力学的突变,揭示出一个约52 meV的强耦合能隙打开。多个相干声子模式,包括3.88、5.28和2.09 THz附近的Ag模,在转变处表现出模式选择性的异常,尤其是3.88 THz声子的重整化行为从高温下的常规非谐衰减转变为低温下的急剧硬化,表明密度波不稳定性与晶格自由度之间存在强耦合,电子-声子相互作用可能起关键作用。在高激发通量下,密度波被非热抑制,得到的温度-通量相图与压力调谐行为相似,但能隙相对稳定,导致耦合比率增大。这些发现确立了La4Ni3O10中的密度波是一种晶格纠缠的、涉及多轨道物理的不稳定性,并证实超快光激发可作为非平衡调控参数有效抑制镍酸盐中的密度波序。
材料
方法
- Pump-probe ultrafast optical spectroscopy
- Rothwarf-Taylor analysis
关键词
- density wave instability
- nonthermal melting
- electron phonon coupling
- lattice entangled instability
- strong coupling gap
亮点
- The 3.88 THz phonon mode exhibits anomalous hardening below T_DW with a power-law exponent switching from 2 to 5.2, indicating strong coupling to the density wave.
- At high fluence, the density wave is nonthermally suppressed while the energy gap remains approximately constant, leading to an enhanced coupling ratio 2Δ/k_B T_DW ≈ 6.6.
- A phonon mode at 5.62 THz emerges only below T_DW, possibly due to zone folding from symmetry lowering.
- The density wave in La4Ni3O10 is a lattice-entangled instability involving multiple phonon modes, distinguishing it from bilayer La3Ni2O7.
结论
- Ultrafast optical spectroscopy reveals a strong-coupling density wave gap of ≈52 meV in La4Ni3O10 single crystals at T_DW ≈ 136 K.
- Multiple coherent phonons exhibit mode-selective anomalies, indicating strong electron-phonon coupling and multiorbital physics.
- The density wave is nonthermally suppressed at high excitation fluences, producing a temperature-fluence phase diagram analogous to pressure tuning.
- These results establish the density wave as a lattice-entangled instability and highlight ultrafast optical excitation as a nonequilibrium tuning parameter for nickelates.
主要论断
- Quasiparticle relaxation dynamics reveal the opening of a strong-coupling 52 meV density-wave gap at T_DW ≈136 K.
- 证据: Slow quasiparticle component lifetime τ_slow shows critical slowing down at T_DW; Rothwarf-Taylor analysis yields a zero-temperature gap 2Δ(0) ≈52 meV; ratio 2Δ/k_BT_DW ≈ 4.4, exceeding the BCS weak-coupling value of 3.5.
- A phonon mode at 3.88 THz undergoes anomalous renormalization strongly coupled to the DW instability, indicating strong electron-phonon coupling and multiorbital involvement.
- 证据: Frequency of 3.88 THz mode follows standard anharmonic decay (exponent n=2) above T_DW, but exhibits pronounced hardening with n≈5.2 below T_DW; eigenvector involves apical oxygen motion, Ni-O plane buckling, and La displacements; other phonons show contrasting behaviors (softening of 3.55 THz and 2.09 THz modes), highlighting mode-selective coupling.
- Intense optical excitation suppresses the density wave nonthermally, producing a temperature-fluence phase diagram analogous to pressure tuning, while the gap remains relatively stable.
- 证据: At high fluence (130 μJ/cm2), T_DW is suppressed to 95 K, but the extracted gap remains ≈55 meV, enhancing 2Δ/k_BT_DW to 6.6; critical fluence for DW melting increases with decreasing temperature; steady-state laser heating accounts for only an 8 K temperature rise, far less than the 40 K suppression, confirming a nonthermal mechanism.
研究流程
- sample_preparation — High-quality single crystals of La4Ni3O10 were obtained via optical floating-zone growth under oxygen pressure.
- 材料: La4Ni3O10 single crystals; optical floating-zone furnace; O2 atmosphere (18-22 bar)
- 方法: high-pressure optical floating-zone growth
- 观察: high-quality single crystals grown
- ultrafast_optical_spectroscopy — Ultrafast pump-probe spectroscopy captures sub-picosecond quasiparticle dynamics and coherent lattice vibrations across the density-wave transition.
- 材料: pump-probe setup; 1-MHz Yb-fiber femtosecond oscillator; optical parametric amplifier; 800 nm (1.55 eV) pulses
- 方法: transient differential reflectivity measurements; temperature-dependent scans at weak and high fluences
- 观察: biexponential quasiparticle relaxation with fast and slow components; coherent phonon oscillations observed across T_DW
- data_analysis — A strong-coupling density-wave gap opens at T_DW; multiple phonons show mode-selective electron-phonon coupling; nonthermal melting of DW order is evidenced by the fluence-dependent phase diagram.
- 材料: transient reflectivity traces; fast Fourier transform spectra
- 方法: biexponential fitting of QP relaxation; Rothwarf-Taylor model for gap extraction; phonon frequency tracking and power-law fitting; phase diagram construction
- 观察: DW gap 2Δ(0) ≈52 meV, ratio 2Δ/k_BT_DW ≈4.4 (strong coupling); phonon modes at 3.88, 5.28, 2.09 THz exhibit mode-selective anomalies; 3.88 THz mode hardens below T_DW (exponent n≈5.2 vs n=2 above); high fluence suppresses T_DW while gap remains ≈55 meV, ratio increases to 6.6; multiple emergent phonon modes; 2.09 THz softens below T_DW; phonon at 5.62 THz appears only below T_DW
- interpretation — The density wave in La4Ni3O10 is a lattice-entangled instability with strong electron-phonon coupling and multiorbital character; ultrafast optical excitation provides a nonequilibrium pathway to suppress and tune density-wave order in nickelates.
- 材料: temperature-fluence phase diagram; comparison with pressure-tuned behavior
- 方法: comparison with literature on pressure effects; analysis of electron-phonon coupling via phonon eigenvectors and isotope effect
- 观察: nonthermal suppression of T_DW without a proportional reduction of the gap; enhanced 2Δ/k_BT_DW under high fluence; lattice-entangled instability involving multiple phonon modes and multiorbital physics